AFM ve farmaceutické technologii 3. / AFM in Pharmaceutical Technology 3.

Ščuryová, Veronika

January 2015

Charles University in Prague Faculty of Pharmacy in Hradec Králové Department of Pharmaceutical Technology Student: Veronika Ščuryová Supervisor: doc. RNDr. Pavel Doležal, CSc. Title of thesis: AFM in Pharmaceutical Technology 3 The theoretical part deals first with the construction of AFM microscope, the principle of the method, determining the surface topography and regimes which can be used. Described therein are distinct advantages over previous traditional methods but also its pitfalls. Next, I compare the results of measurements using AFM and declared size and devote also determine the shape of the particles. Experimental part is focused first on the detailed description of sample preparation for AFM measurement of nanoparticles. This procedure was followed by practical use to characterize the magnitude of the four types of commercially available nanoparticles Chromeonov (Sigma-Aldrich) using atomic force microscopy. The laboratory prepared Ag- nanoparticles could not be evaluated due to of technical and methodological reasons. The magnitude of the measured results nanoparticles were processed in histograms, which provide a description of the distribution of the measured values of the nanoparticle size. I found that compared to the size of the nanoparticles declared by the manufacturer are...

AFM ve farmaceutické technologii 2. / AFM in pharmaceutical technology 2.

Princová, Tatiana

January 2014

The theoretical part deals with topics related to the formation of nanofibers and nanomembranes by different ways of electrospinning. The literary search focused on "medicated nanofibrous membrane" gives recent information on nanomembranes containing drugs and also shows the perspective of the use of nanofibers in this area. The experimental part deals with AFM parameters needed for characterisation of the samples of six selected polymer nanomembranes with the content of naproxen, folic acid and diosmin. The appearance and thickness of the nanofibers was examined. The set up parameters of the AFM measurements allowed to observe the distribution of the drug in non- crystalline state within the nanofibers, regular fibrous shapes of crystal-like nanofibers as well as distinguished nanoingots of the polymers. The captured scans are stored and available for further analysis. Keywords: electrospinning, nanomembrane, naproxen, AFM, drug-loaded nanofibers

Studying liquid-phase heterogeneous catalysis using the atomic force microscope

Young, Matthew J.

January 1900

Doctor of Philosophy / Department of Chemical Engineering / Peter H. Pfromm / Characterization of the interactions of hydrogen with catalytic metal surfaces and the mass transfer processes involved in heterogeneous catalysis are important for catalyst development. Although a range of technologies for studying catalytic surfaces exists, much of it relies on high-vacuum conditions that preclude in-situ research. In contrast, atomic force microscopy (AFM) provides an opportunity for direct observation of surfaces under or near actual reaction conditions. Tapping-mode AFM was explored here because it expands AFM beyond the usual topographic information toward speciation and other more subtle surface information. This work describes using phase-angle data from tapping-mode AFM to follow the interactions of hydrogen with palladium. Both gas-solid and liquid-solid interfaces were studied. Real-time AFM phase-angle data allowed for the observation of multiphase mass transfer to and from the surface of palladium at atmospheric pressure and room temperature without the need for complex sample preparation. The AFM observations were quantitatively benchmarked against and confirm mass transfer predictions based on bulk hydrogen diffusion estimates. Additionally, they support recent studies that demonstrate the existence of multiple hydrogen states during interactions with palladium surfaces.

Atomic force microscopy

Catalysis

In-situ

Hydrogenation

The Role of Integrins in Cellular Response to Mechanical Stimuli

Thomas, Gawain M.

19 January 2017

Tissue cells exhibit varying responses according to the stiffness of their extracellular matrix (ECM). The mechanism of this stiffness sensing is not fully understood; however, it is known that cells probe stiffness by applying intracellular force to the ECM via integrin-mediated focal adhesions. The bonds between integrins and ECM have been described as “catch bonds�, and it is unclear how ECM viscoelasticity affects these bonds. We have observed the effects of ECM stiffness on the binding strength of integrins to ECM ligands by measuring the dissociation force of individual integrin-ligand bonds of 3T3 fibroblasts on collagen-coated polyacrylamide gels using atomic force microscopy. Results show that integrins exhibit higher rates of activation on stiff substrates. Furthermore, increased matrix stiffness results in the occurrence of larger, multi-bond dissociation events, which suggests that substrate stiffness may affect the cellular response by promoting integrin clustering as well as by modulating the maximum possible force between individual integrins and the ECM.

Atomic Force Microscopy

cell signaling

Cell adhesion

Individual submicrometer particles and biomolecular systems studied on the nanoscale

VanMetre, Holly Sue Morris

01 May 2016

The necessity to explore nanoscopic systems is ever increasing in the world of science and technology. This evolving need to study such physically small systems demands new experimental techniques and methodologies. Atomic force microscopy (AFM) is a versatile technique that can overcome many nanoscopic size limitations. AFM has been utilized in the world of nanotechnology to study physiochemical properties of particles, materials, and biomolecules through characterization of morphology, electrical and mechanical properties, binding interactions, and surface tension, among others. The work discussed herein is largely a report of several novel AFM methodologies that were developed to allow new characterization techniques of individual submicrometer particles and single biomolecular interactions. The effects of atmospheric aerosols on the radiative budget of the earth and climate are largely unknown. For this reason, characterizing the physiochemical properties of aerosols is vital. Since the particles that have relatively long lifetimes in the atmosphere are smaller than one micrometer in size, high resolution microscopy techniques are required to study them. AFM is a suitable technique for single particle studies because it has nanometer spatial resolution, can perform experiments under ambient pressure and variable relative humidity and temperature. These advantages were utilized here and AFM was used to study morphology, organic volume fraction, water uptake, and surface tension of nascent sea spray aerosol (SSA) particles as well as laboratory generated aerosols composed of relevant chemical model systems. The morphology of SSA was found, often times, to be composed of core-shell structure. With complementary microscopy techniques, the composition of the core and the shell was found to be inorganic and organic in nature, respectively. Novel methodology to measure water uptake and surface tension of single substrate deposited particles with AFM was established using chemical model systems. Furthermore, these methodologies were employed on nascent chemically complex SSA particles collected from a biologically active oceanic waveflume experiment. Finally, phase imaging was used to measure organic volume fraction on a single particle basis and was correlated with biological activity. Overall, this suite of single (submicrometer) particle AFM analysis techniques have been established, allowing future systematic studies of increasing complexity aimed at bridging the gap between the simplicity of laboratory generated particles and the complexity of nature. Another nanotechnology topic of interest is studying single biomolecular interactions. Virtually every biological process involves some amount of minute forces that are required for the biomolecular system to function properly. For example, there are picoNewton forces associated with enzymatic motions that are important for enzyme catalysis. The AFM studies reported here use a model enzyme/drug system to measure the forces associated with single molecule adhesion events. Escherichia Dihydrofolate Reductase (DHFR) is a target of cancer therapeutic studies because it can be inhibited by drugs like methotrexate (MTX) that are structurally similar to the natural folate binder but have much higher binding affinity. One of the obstacles of single molecular recognition force spectroscopy (MRFS) studies is the contribution of non-specific forces that create a source of uncertainty. In this study, DHFR and MTX are bound to the surface and the AFM tip, respectively, using several different linking molecules. These linking molecules included polyethylene glycol (PEG) and double stranded DNA (dsDNA) and the distribution of forces was compared to scenarios were a linker was not employed. We discovered that dsDNA and PEG both allow identification and removal of non-specific interaction forces from specific forces of interest, which increases the accuracy of the measurement compared to directly bound constructs. Traditionally, the linker of choice in the MRFS community is PEG. Here, we introduce dsDNA as a viable linker that offers more rigidity than PEG, which may be desirable in future molecular constructs. The majority of the work and data presented in this dissertation supports the establishment of new AFM methodologies that can be used to better explore single biomolecular interactions and individual submicrometer particles on the nanoscale.

publicabstract

Aerosols

Atomic force microscopy

Chemistry

Exploring Atomic Force Microscopy To Probe Charge Transport Through Molecular Films And For The Development Of Combinatorial Force Microscopy

Chisholm, Roderick A.

06 1900

Since the invention of the atomic force microscope (AFM), this technology has had profound implications in the study of material science and molecular biology. The ability to visualize and perform quantitative analysis of the nanoscale properties of surfaces has provided great insights into these nanoscale landscapes. The present dissertation manuscript exploits this technology for the measurement of charge transport through molecular films and the development of combinatorial force microscopy. Firstly, this work probed, for the first time, charge transport through molecular films derived from diazonium salts grafted to carbon electrodes using conductive atomic force microscopy. We found the charge transport properties of a molecular junction are dependent upon the chemical structure of the molecular film. We also investigated the effect of molecular film compression and deformation has on charge transport. In this, we observed increases in current densities associated with increases in applied load to the molecular film. Furthering these initial findings, PPF/NAB/Cu molecular junctions were fabricated having junction sizes ranging between micro-scale and nanoscale. The charge transport experiments reveal an agreement of electron transport properties between the metal deposited PPF/NAB/Cu junction and a PPF/NAB/Cu AFM tip junction at an applied load of approximately 60nN. This form of molecular layer charge transport control may potentially open new horizons for integration of molecular films into the microelectronics industry. This dissertation manuscript also describes the development of the quantitative interrogation opposing chemical libraries involved in combinatorial inverted atomic force microscopy. Tipless cantilevers were patterned with chemically modified nanorods. These modified nanorods were then used as chemical identifiers during a combinatorial force microscopy experiment and for the first time 16 interactions were monitored within one experiment in a continuous medium. Thus, providing excellent for the validation that combi-AFM is a truly quantitative high-throughput technology.

atomic force microscopy

force microscopy

diazonium

Structural studies of heterogeneous amyloid species of lysozymes and de novo protein albebetin and their cytotoxicity

Zamotin, Vladimir

January 2007

A number of diseases are linked to protein folding problems which lead to the deposition of insoluble protein plaques in the brain or other organs. These diseases include prion diseases such as Creutzfeld-Jakob disease, Alzheimer's disease, Parkinson's disease and type II (non-insulin dependent) diabetes. The protein plaques are found to consist of amyloid fibrils - cross-beta-sheet polymers with the beta-strands arranged perpendicular to the long axis of the fibre. Studies of ex vivo fibrils and fibrils produced in vitro showed that amyloid structures possess similar tinctorial and morphological properties. These suggest that the ability to form amyloid fibrils is an inherent property of polypeptide chains. The aims of this thesis were to investigate the structural properties of cytotoxic amyloid and examine the involved mechanisms. The model proteins used in the studies were the equine and hen lysozymes and de novo designed protein albebetin. Lysozymes are naturally ubiquitous proteins. Equine lysozyme belongs to an extended family of structurally related lysozymes and α-lactalbumins and can be considered as an evolutional bridge between them. Hen lysozyme is one of the most characterized protein and its amyloidogenic properties were described earlier. De novo protein albebetin and its constructs are designed to perform the function of grafted polypeptide sequence. Fibrils of equine lysozyme are formed at acidic pH and elevated temperatures where a partially folded molten globule state is populated. We have shown that lysozyme assembles into annular and linear protofilaments in a calcium-dependent manner. We showed that albebetin and its constructs are inherently highly amyloidogenic under physiological conditions. Fibrillation proceeds via multiple pathways and includes a hierarchy of amyloid structures ranging from oligomers to protofilaments and fibrils, among which two distinct types of oligomeric intermediates were characterized. Pivotal oligomers comprise of 10-12 monomers and on-pathway amyloid-prone oligomers constitute of 26-30 molecules. We suggest that transformation of the pivotal oligomers into the amyloid-prone ones is a limiting stage in albebetin fibrillation. Cytotoxic studies of albebetin amyloid species have revealed that initial, pivotal oligomers do not effect on cell viability while amyloid-prone ones induce cell death. We suggest that oligomeric size is important for the stabilizing cross-beta-sheet core which is crucial for cell toxicity. Cytotoxic studies of both oligomers and fibrils of hen lysozyme have revealed that both species induce cell death. The amyloid sample containing cross-β-sheet oligomers induces an apoptosis-like cell death. The oligomers without cross-β-sheet appeared to be non-toxic, indicating that the stabilization of this structural pattern is critical for the induced toxicity. In contrast, the fibrils induce more rapid, necrosis-like death. These studies gained insights into a structure–function relationship of different forms of amyloid and general pathways of cell death. This is an important step in understanding the mechanisms of amyloid-associated degeneration and defining specific therapeutic targets.

amyloid

cytotoxicity

atomic force microscopy

Biophysics

Biofysik

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

29 September 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

Force Transduction and Strain Dynamics through Actin Stress Fibres of the Cytoskeleton

Guolla, Louise

29 September 2011

It is becoming clear that mechanical stimuli are critical in regulating cell biology; however, the short-term structural response of a cell to mechanical forces remains relatively poorly understood. We mechanically stimulated cells expressing actin-EGFP with controlled forces (0-20nN) in order to investigate the cell’s structural response. Two clear force dependent responses were observed: a short-term local deformation of actin stress fibres and a long-term force-induced remodelling of stress fibres at cell edges, far from the point of contact. We were also able to quantify strain dynamics occurring along stress fibres. The cell exhibits complex heterogeneous negative and positive strain fluctuations along stress fibres, indicating localized dynamic contraction and expansion. A ~50% increase in myosin contractile activity is apparent following application of 20nN force. Directly visualizing force-propagation and stress fibre strain dynamics has revealed new information about the pathways involved in mechanotransduction which ultimately govern the downstream response of a cell.

Atomic Force Microscope

Actin

Cytoskeleton

Mechanotransduction

Biophysics

AFM-Based Mechanical Nanomanipulation

January 2011

Advances in several research areas increase the need for more sophisticated fabrication techniques and better performing materials. Tackling this problem from a bottom-up perspective is currently an active field of research. The bottom-up fabrication procedure offers sub-nanometer accurate manipulation. At this time, candidates to achieve nanomanipulation include chemical (self-assembly), biotechnology methods (DNA-based), or using controllable physical forces (e.g. electrokinetic forces, mechanical forces). In this thesis, new methods and techniques for mechanical nanomanipulation using probe force interaction are developed. The considered probes are commonly used in Atomic Force Microscopes (AFMs) for high resolution imaging. AFM-based mechanical nanomanipulation will enable arranging nanoscale entities such as nanotubes and molecules in a precise and controlled manner to assemble and produce novel devices and systems at the nanoscale. The novelty of this research stems from the development of new modeling of the physics and mechanics of the tip interaction with nanoscale entities, coupled with the development of new smart cantilevers with multiple degrees of freedom. The gained knowledge from the conducted simulations and analysis is expected to enable true precision and repeatability of nanomanipulation tasks which is not feasible with existing methods and technologies.

Applied sciences

Nanomanipulation

Atomic force microscopy

Nanoscience